An input current channel device is described. This device comprises a first terminal for receiving a reference signal; a second terminal for receiving a first target signal; a pass through device coupled to the first terminal, the pass through device operative for transmitting a delayed reference signal in response to receiving the reference signal; a first combination logic device coupled to the first terminal and the second terminal, the first combination logic device operative for transmitting a first combination logic signal in response to receiving the reference signal and the first target signal; a selection device coupled for receiving the delayed reference signal, the first combination logic signal, and a first synchronization signal, the selection device operative for selectively transmitting a second synchronization signal, and wherein selectively transmitting the second synchronization signal reduces skew between the reference channel and the first target channel.
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1. An input current channel device for use with an optical disk drive system, comprising:
a first terminal for receiving a reference signal;
a second terminal for receiving a first target signal;
a pass through device coupled to the first terminal, the pass through device operative for transmitting a delayed reference signal in response to receiving the reference signal;
a first combination logic device coupled to the first terminal and the second terminal, the first combination logic device operative for transmitting a first combination logic signal in response to receiving the reference signal and the first target signal;
a selection device coupled for receiving the delayed reference signal, the first combination logic signal, and a first synchronization signal, the selection device operative for selectively transmitting a second synchronization signal, and
wherein selectively transmitting the second synchronization signal reduces skew between a reference channel that conveys the reference signal and a first target channel that conveys the first target signal.
2. The input current channel device 1, wherein the second synchronization signal is used in writing data to an optical disk in the optical disk drive system.
3. The input current channel device of
4. The input current channel device of
5. The input current channel device 1, wherein the skew is approximately 10 ps and the propagation delay is less than approximately 1 ns.
6. The input current channel device of
7. The input current channel device of
8. The input current channel device of
9. The input current channel device of
10. The input current channel device of
11. The input current channel device of
12. The input current channel device of
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This amendment claims priority under 35 USC §119(e)(1) of provisional application No. 61/186,184, filed Jun. 11, 2009.
With the evolution of electronic devices, there is a continual demand for enhanced speed, capacity and efficiency in various areas including electronic data storage. Motivators for this evolution may be the increasing interest in video (e.g., movies, family videos), audio (e.g., songs, books), and images (e.g., pictures). Optical disk drives have emerged as one viable solution for supplying removable high capacity storage. When these drives include light sources, signals sent to these sources should be properly processed to reduce potential damage in appropriate light emission.
The input current channel device may be better understood with reference to the following figures. The components within the figures are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the invention. Moreover, in the figures, like reference numerals designate corresponding parts or blocks throughout the different views.
While the input current channel device is susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and subsequently are described in detail. It should be understood, however, that the description herein of specific embodiments is not intended to limit the input current channel device to the particular forms disclosed. In contrast, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the input current channel device as defined by this document.
As used in the specification and the appended claim(s), the singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise. Similarly, “optional” or “optionally” means that the subsequently described event or circumstance may or may not occur, and that the description includes instances where the event or circumstance occurs and instances where it does not.
Turning now to
Also, the controller 102 sets the enable signal for switching some current channels of the laser driver 110, which arranges a data writing pulse. In the case of data reading, the controller 102 may only set the DC current by disabling the switching and applying the indicated input current. In the case of data writing, the controller 102 applies some adjustment signals, or enable-switching signals, to arrange the writing pulse waveform as a combination of switching timing, which also changes the power level by different indicated current of each channel. The controller 102 can arrange these indicated currents based on the Monitor. PD 104 output with some detecting function in the RF preamplifier 106. At the very least, this controller has two controlling levels for the reading power and the writing power. Sometimes the controller may get the top, bottom, or average level of a writing pulse and calculate to control some power levels independently.
As illustrated in this figure, the laser driver 110 sends a signal that prompts an associated light source 115 (e.g., laser diode) to emit light. The light source 115 may emit light at any of a number of wavelengths (e.g., 400 nm, 650 nm, 780 nm). Light from this source contacts an associated optical media 117, such as a compact disc (CD), blue ray device (Blu-ray), or digital versatile disk (DVD). Light contacting the optical media can either facilitate data storage or data retrieval from the optical media 117.
At a high level, the LDD 110 may include a current generator 120. Generally, the current generator 120 receives some input signals 123 associated with several input channels, which have an associated input current. This current generator 120 works in tandem with a current driver 140 and produces a gain for the input current. As a result, the current generator 120 and current driver 140 control the amount of current for each output channel 145. For, the input signals that the current generator 120 receives, it transmits output signals that a current switch 130 receives. The current switch 130 decides which of the input channels should be turned on or turned off. For the channels that should be turned on, the current switch 130 makes those channels active. Similarly, the current switch 130 inactivates the channels that should be turned off and transmits output signals reflecting this change. The current driver 140 receives these output signals from the current switch 130 as input signals. The current driver 140 is the last current gain stage and drives the laser diode directly. In other words, the output signals from the current driver 140 also serve as output signals for the LDD 110, which are used in driving the lasers, or the light source 115 (see
In addition to the above-mentioned devices, the LDD 110 includes additional components. A serial interface (I/F) 150 has several inputs 155 (e.g., serial data enable, serial data, serial clock) that may be used for an enable, feature selection, or setting the gain. Like the serial interface 150, the timing generator 160 receives various channel enable inputs 165. Though there are five channel enable inputs that are shown in
As indicated in
To achieve an effective, or fast, rise time and fall time and generate a correct, or well-defined, write current pulse for good write marks in disk, the output current from the LDD 110 is usually a combination of several current channels. With the ICCD 167, each target channel can be turned on and off via some switching control, or synchronization, signals from the controller chip as further described with reference to
A buffer stage 220 receives the differential enable signals from the receiver stage 210. This buffer stage includes at least one buffer associated with each of the receivers in the receiver stage 210. More specifically, buffers 221-224 receive differential signals from the receivers 211-214, respectively. These buffers may be a_ECL or some other suitable type buffer to convert receivers' output signals to the correct voltage levels for the following stages. Each of these buffers has four input terminals of which two connect to the receiver output terminals 216, one connects to the enable signal and the other connects to some biasing voltage. The buffers 221-224 transmits buffered enable signals on their associated output terminals 226 that have a voltage appropriate for re-synchronization, such that output voltage level of 222, 223, and 224 is one VBE lower than those of the buffer 221. Though shown here is one VBE, other shifting voltage levels are equally applicable.
Finally, the re-synchronization stage 230 receives the buffered enable signals from the buffer stage 220. This re-synchronization stage has combinational logic devices associated with buffers. For example, the combinational logic device 231 is associated with the buffer 221 and the combinational logic device 234, which is associated with the buffer 224. In addition, the combinational logic devices 232-234 also include input terminals 235 for receiving a digital synchronization signal. For example, this digital synchronization signal may be a two-bit digital signal, such as signal 155 transmitted by the serial interface 150 described with reference to
As the re-synchronization stage 230 produces these synchronized enable signals, other devices within the LDD 110 may use these signals. The timing generator 150 transmits synchronized enable signals on output terminals 236 to the current switch 130. This current switch uses these synchronized enable signals in either in enabling or disabling the input channels 123 (see
In addition, the receiver illustrated with the circuit diagram 300 also includes emitter followers, resistors for level shifting and a feedback path. Active device 320 (Q0) is an input of a first emitter follower biased via device 322 (Q4) and device 324 (R2); similarly, active device 330 (Q1) is an input of a second emitter follower biased via device 332 (Q4) and device 334 (R2). Device 326 (C1) serves as a bypass capacitor for both of these emitter followers. In selecting sizes or characteristics for these devices, one can select a threshold voltage of approximately 0.7V for the transistors, a resistance of approximately 1.2K, and capacitance of approximately 0.5 pF. Device 340 (R0) and device 342 (R1) can provide level shifting. Device 350 (C2) and device 352 (C3) provide a feed forward path that speeds up the signal transitions between different voltage levels. Device 360 (Q2) and device 362 (Q3) are clamp diodes that limit voltage difference between those two output terminals 370 and 372. The terminals 307, 310, and 302 may correspond to the input terminals 215 for any of the receivers of
Turning now to
Logic functions can be used in aligning pulse edges. As shown in this figure, if an “AND” function is used, one can line up the rising edges of the target channels with the reference channel if target channel's edge is leading. For example, the plot 527 is the outcome of “ANDing” the plot 506 with the plot 507, which results in eliminating the region 511 and aligning the rising edges of the write pulse. If an “OR” function is used, one can line up the falling edges with the reference channel if target channel's edge is lagging. For example, the plot 529 is the outcome of “ORing” the plot 506 with the plot 509, which results in adding a region 531 and aligning the falling edges. Instead of using the plot 507 as the enable signal associated with target channel EW3, the plot 527 is used as the new enable signal for target channel EW3.
Returning to
Each of the output current signals 145 is a superposition of the output currents from the associated input current channels. In
Alternative implementations may exist by changing either the type of logic functions or the type of CMOS combination logic gates used in implementing the function. Though this implementation is essentially balanced, it can be slow in terms of propagation delay and rise/fall time. In addition, the circuit diagram 600 includes a multiplexer 610 for transmitting a synchronized current enable signal. In this implementation, the multiplexer's input terminals 611-612 connect to this digital synchronization signal may be a two-digital signal, such as signal 155 transmitted by the serial interface 150 described with reference to
Turning now to
While various embodiments of the input channel current device have been described, it may be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible that are within the scope of this system. Although certain aspects of the channel input current device may be described in relation to specific techniques or structures, the teachings and principles of the present system are not limited solely to such examples. All such modifications are intended to be included within the scope of this disclosure and the present channel input current device and protected by the following claim(s).
Li, Shengyuan, Dina, Marius V., Ranmuthu, Indumini W.
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Nov 05 2009 | RANMUTHU, INDUMINI W | Texas Instruments Incorporated | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 023549 | /0360 | |
Nov 12 2009 | DINA, MARIUS V | Texas Instruments Incorporated | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 023549 | /0360 | |
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